Homotopic Redistribution of Functional Connectivity in Insula-centered Diffuse Low-grade Glioma

Overview

Journal Neuroimage Clin

Publisher Elsevier

Specialties Neurology
Radiology

Date 2021 Jan 28

PMID 33508623

Citations 14

Authors

Fabien Almairac

Jeremy Deverdun

Jerome Cochereau

Arthur Coget

Anne-Laure Lemaitre

Sylvie Moritz-Gasser

Hugues Duffau

Guillaume Herbet

Affiliations

Soon will be listed here.

Abstract

Objective: In the event of neural injury, the homologous contralateral brain areas may play a compensatory role to avoid or limit the functional loss. However, this dynamic strategy of functional redistribution is not clearly established, especially in the pathophysiological context of diffuse low-grade glioma. Our aim here was to assess the extent to which unilateral tumor infiltration of the insula dynamically modulates the functional connectivity of the contralesional one.

Methods: Using resting-state functional connectivity MRI, a seed-to-ROI approach was employed in 52 insula-centered glioma patients (n = 30 left and 22 right) compared with 19 age-matched healthy controls.

Results: Unsurprisingly, a significant decrease of the inter-insular connectivity was observed in both patient groups. More importantly, the analyses revealed a significant increase of the contralesional insular connectivity towards both cerebral hemispheres, especially in cortical areas forming the visual and the sensorimotor networks. This functional redistribution was not identified when the analyses were performed on three control regions for which the homologous area was not impaired by the tumor. This overall pattern of results indicates that massive infiltration of the insular cortex causes a significant redeployment of the contralesional functional connectivity.

Conclusion: This general finding suggests that the undamaged insula plays a role in the functional compensation usually observed in this patient population, and thus provides compelling support for the concept of homotopic functional plasticity in brain-damaged patients.

Citing Articles

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Epilepsy alters brain networks in patients with insular glioma.

He Q, Yang Z, Xue B, Song X, Zhang C, Yin C CNS Neurosci Ther. 2024; 30(6):e14805.

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Smolders L, De Baene W, Rutten G, van der Hofstad R, Florack L Brain Struct Funct. 2024; 229(5):1209-1223.

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Brain Plasticity Profiling as a Key Support to Therapeutic Decision-Making in Low-Grade Glioma Oncological Strategies.

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PMID: 37345051 PMC: 10216571. DOI: 10.3390/cancers15102714.

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